JPH07177400A - Video camera - Google Patents

Abstract

PURPOSE:To use a general-purpose CCD package larger than the diameter of an optical path space without extending the diameter of the optical path space, and to position the CCD package without using positioning components. CONSTITUTION:Notched grooves 10a are formed at the four places of a cylindrical part 10 of a front cylindrical body 7 with the optical path space 11 inside of it. Then, the respective four corners of an optical filter 14 and the CCD package 16, both of which are rectangular, are inserted to the respective notched grooves 10a so as to house the optical filter 14 and the CCD package 16 within the optical path space 11.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a small single-panel video camera.

[0002]

2. Description of the Related Art Video cameras can be classified into broadcasting stations, consumer products and industrial products. In the fields of consumer products and industrial products, downsizing of video cameras is used for expanding the range of applications and downsizing devices used. Then, the present applicant has previously described FIG. 12 to FIG.
Proposed a small video camera shown in (Japanese Patent Application No. 3-29).
3463 application documents).

12 to 14, the video camera has a case body A in which a front block body B, a substrate block body C and a rear block body D are housed. As shown in detail in FIGS. 15 and 16, the front block body B is inserted into the front side of the case body A, and
The outside is almost covered with. An optical path space 11 for entering light is formed in the front cylindrical body 7, and a notch groove 10a in the optical axis direction having a rear end is formed in the cylindrical portion 10 of the front cylindrical body 7 at four locations. There is. A screw portion 10b is formed on the outer periphery of the tubular portion 10, and a positioning protrusion 50 is provided at the rear end of the tubular portion 10. And
In the cylindrical portion 10, the image frame plate 13, the optical filter 14, the packing member 15, and the back plate 1 are arranged in order from the front.
The CCD package 16 (solid-state image pickup device package) fixed to 7 is inserted, and finally the adjusting ring member 18 is screwed into the screw portion 10b, whereby the above-mentioned respective components are fixed.

The CCD package 16 has a substantially circular shape, and a rectangular image pickup surface 16a having an aspect ratio of 4: 3 is provided on the front side thereof.
Is provided. And this CCD package 16
Is positioned on the back plate 17 on the rear surface side, and the positioning protrusion 50 is positioned in the positioning groove 51 of the back plate 17.
Is inserted and the back plate 17 is positioned in the rotational direction with respect to the front cylindrical body 17.

[0005]

However, the above-mentioned substantially circular CCD package 16 is not generally commercially available. Generally, a commercially available CCD package has a rectangular shape (rectangular shape or square shape), and its diagonal dimension is slightly larger than the diameter of the optical path space 11. Therefore, the substantially circular CCD package 16 is specially manufactured so that it can be housed in the optical path space 11, and the cost is very high.

Further, since the positioning of the CCD package 16 in the rotational direction is performed via the back plate 17, the mounting accuracy of the back plate 17 affects the positioning of the CCD package 16.

Therefore, according to the present invention, a versatile rectangular CCD package can be used without increasing the diameter of the optical path space, and the positioning accuracy can be improved by positioning the CCD package without any positioning component. It is an object to provide a video camera which is

[0008]

In order to achieve the above object, a video camera of the present invention is provided with a tube portion of a front tube body having an optical path space therein, and an optical axis direction opened at a rear end of the tube section. Notch grooves are provided at four locations, and four corners of a rectangular CCD package are inserted into each notch groove to form a CCD.
The package is arranged in the optical path space.

[0009]

Since the four corners of the rectangular CCD package are inserted into the respective cutout grooves of the cylindrical portion, the CCD package having a diagonal dimension slightly larger than the diameter of the optical path space can be accommodated in the optical path space. Positioning in the rotational direction is performed by locking the four corners in each notch groove.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. 1 to 11 show one embodiment of the present invention. FIG. 1A is an exploded perspective view of the front block body B,
2 is a perspective view of the video camera, FIG. 3 is an exploded perspective view of the video camera, FIG. 4 is a vertical sectional view of the video camera, and FIG.
The cross-sectional views of the video cameras are respectively shown in FIG.
1 to 5, the video camera is configured by assembling a front block body B, a substrate block body C, and a rear block body D to a case body A.

The case body A is made of a material having good heat conductivity, and has a slender tubular shape whose cross-sectional outer shape is an octagon. Although this octagon is not a regular octagon, it is point-symmetric with respect to the center of the optical axis. Specifically, it is configured by forming a quadrangle as a base and forming inclined surfaces 2 which are notched at 45 degrees at four corners of the four surfaces 1. The four surfaces 1 are formed with a plurality of grooves 3 in the longitudinal direction to have a large total surface area, and each surface 1 is provided with a positioning groove portion 4. As shown in FIG. 2, the camera holder 40 is positioned by the groove portion 4 and mounted on the case body A. Further, screw insertion holes 6 are formed in the front end portions of the four inclined surfaces 2 and the rear end portions of the three inclined surfaces 2, respectively.

The front block body B is inserted in the front side of the case body A, as shown in detail in FIG.
The front cylindrical body 7 of the front block body B is the front portion 8
The mounting portion 9 and the tubular portion 10 are integrally configured. An optical path space 11 for entering light is formed on the entire inner side of these, and the vertical cross section of the optical path space 11 is formed in a circular shape.

The front portion 8 is arranged so as to project from the front end surface of the case body A, and a ring-shaped lens mounting reference surface 8a is formed on the front surface of the front portion 8. The mounting portion 9 has an octagonal shape corresponding to the inner surface dimension of the case body A, and is arranged on the front end side in the case body A. Then, screw holes 9a are formed in the four inclined portions of the front portion 8, and the screw insertion holes 6 of the case body A are inserted into the screw holes 9a.
The screw 12 inserted in is inserted. This screw 12
The front cylindrical body 7 is fixed to the case main body A by the fastening force.

The cylindrical portion 10 has a notch groove 10 extending in the optical axis direction.
a is formed at four places, and each of the cutout grooves 10a is formed in the cylindrical portion 10a.
It opens at the rear end. An image frame plate 13, an optical filter 14, a packing member 15, and a CCD (solid-state image sensor) package 16 are sequentially inserted into the cylindrical portion 10 from the front. Further, a threaded portion 10b is formed on the outer circumference of the tubular portion 10, and an adjusting ring member 18 is screwed into the threaded portion 10b.

The image frame plate 13 has a substantially disk shape having the same size as the inner diameter of the cylindrical portion 10, and a large rectangular opening 13a is formed in the center thereof. The aspect ratio of the opening 13a is set to be the same as that of the image pickup surface 16a of the CCD package 16. Projections 13b are integrally provided on the outer periphery of the image frame plate 13 and at positions corresponding to the four corners of the opening 13a. These four protrusions 13b
Is inserted into each notch groove 10a of the cylindrical portion 10,
The image frame plate 13 is positioned in a direction other than the optical axis direction by locking the protrusion 13b in the notch groove 10a.

The optical filter 14 has a rectangular shape and is constructed by laminating a low pass filter, an infrared cut filter and the like. The diagonal dimension d ₁ of the optical filter 14 is set to be slightly larger than the diameter d ₂ of the optical path space 11, and the four corners of the optical filter 14 have the cutout grooves 1 of the tubular portion 10.
0a, respectively. The optical filter 14 is positioned in a direction other than the optical axis direction by locking its four corners in the cutout grooves 10a.

The packing member 15 is shown in FIGS.
As shown in detail in (b), a ring-shaped portion 15 formed of an elastic material and having an outer diameter slightly smaller than the diameter d ₂ of the optical path space 11.
a. The opening 15 inside the ring-shaped portion 15a
b has a rectangular shape, and the aspect ratio of this opening 15b is CC.
The ratio is set to be the same as that of the image pickup surface 16a of the D package 16. A filter holding portion 15c and a CCD holding portion 15d are provided so as to project on the outer peripheral sides of the front and rear surfaces of the ring-shaped portion 15a, and at four positions in the vertical and horizontal directions. Ring-shaped part 15a
The rear side of the optical filter 14 is inserted into the space formed by the front surface of the optical filter 14 and the filter holding portion 15c. The front side of the CCD package 16 is inserted into the space formed by the rear surface of the ring-shaped portion 15a and the CCD holding portion 15d.

Further, projections 15e are respectively provided on the outer peripheral end surfaces of the ring-shaped portion 15a, the filter holding portions 15c and the CCD holding portion 15d, and between the projections 15e opposed to the center of the ring-shaped portion 15a. Is substantially the same as the diameter of the optical path space 11. Further, locking projections 15f are respectively provided so as to project on the outer peripheral end surface of the ring-shaped portion 15a and on positions diagonally extending from the opening 15b. Are inserted into the respective cutout grooves 10a.

Further, a crimping protrusion 15g is provided on the inner peripheral side of the front surface of the ring-shaped portion 15a along the outer periphery of the opening 15b. On the front surface of the ring-shaped portion 15a, the crimping protrusion 15g, each filter holding portion 15c, and each locking protrusion 15f.
Rib portions 15h connecting between and are respectively projected.

As shown in detail in FIGS. 1A and 1B, the CCD package 16 has a rectangular outer shape, and its diagonal dimension d ₁ is larger than the diameter d ₂ of the optical path space 11. It is composed a little larger. A rectangular image pickup surface 16a having an aspect ratio of 4: 3 is provided on the front side of the CCD package 16, and a glass body 16b covers the front of the image pickup surface 16a. Also, CCD package 16
A back plate 17 is fixed to the rear surface of the back plate 17. The back plate 17 has a substantially disk shape having a size slightly larger than the inner diameter of the cylindrical portion 10. Then, as shown in FIG.
The four corners of the CCD package 16 are inserted into the respective cutout grooves 10 a of the tubular portion 10, and the four corners are formed into the cutout grooves 10.
Positioning in a direction other than the optical axis direction is achieved by being locked to a. In this embodiment, the CCD package 1
Although the outer shape of 6 is rectangular, the present invention can be applied even if it is square.

The adjusting ring member 18 has a threaded portion 1 on its inner circumference.
8a is formed, and this screw portion 18a is formed on the cylindrical portion 1a.
It is screwed into the 0 screw part 10b. Adjustment ring member 1
A ring-shaped pressing portion 18b is provided on the rear end surface of the back plate 8, and the pressing portion 18b presses the rear surface of the back plate 17. In other words, the adjustment ring member 18 attaches the CCD package 16 to the packing member 15 via the back plate 17.
Is pressed against.

As shown in FIGS. 3 and 8, the board block C is mainly composed of an inner case 20 and a board group housed in the inner case 20. The board group is composed of two rigid flexible boards 21 and 22 in which one middle layer of the rigid board section constitutes a flexible board section, and one rigid flexible board 21 is a front rigid board section 21a and a first rigid board section 21b.
And a flexible board portion 21c for connecting between the board portions 21a and 21b. The front side rigid board portion 21a is arranged on the rear surface of the adjusting ring member 18, and each terminal 16c of the CCD package 16 is soldered to the front side rigid board 21a.

The other rigid flexible substrate 22 includes a second rigid substrate portion 22a, a flexible substrate portion 22b, a third rigid substrate portion 22c and a flexible substrate portion 22d.
And a rear side rigid board portion 22e. The rear rigid board portion 22e is fixed to the rear panel 29 side described below, and each terminal of the external connection connector 33 described below is soldered to the rear rigid board 22e. The first rigid board portion 21b, the second rigid board portion 22a, and the third
The rigid board portion 22c is arranged in parallel with the rigid board portion 22c at a constant interval, and each of the rigid board portions 21b, 22a, 22c is arranged.
The electronic components 23 are mounted on both surfaces of each.

The first rigid board portion 21b and the second rigid board portion 22a are electrically connected via a first connector 24. A second connector 25 is interposed between the second rigid board portion 22a and the third rigid board portion 22c, and the board portions 2 of both boards are also provided by the second connector 25.
2a and 22c are electrically connected.

The first rigid board portion 21b and the second rigid board portion 22a have the same length, but the third rigid board portion 22c is longer than these. A converter 23a, which is an electronic component having a large size and high heat generation, is mounted on an extended portion of the third rigid board portion 22c.

The substrate block body B is fixed to the rear block body D by the connecting means 32 described below through the third rigid substrate portion 22c.

The inner case 20 is made of a material having good conductivity, springiness, and thermal conductivity, and is composed of an upper case member 20a and a lower case member 20b. The upper case member 20a has a substantially flat plate shape, the lower case member 20b has a substantially U shape, and the upper case member 20a and the lower case member 20b have first to third rigid board portions 21b,
22a and 22c are covered almost entirely. Substrate support slits 26 are formed at the front end positions of the upper case member 20a and the lower case member 20b, respectively, and the first to third rigid substrate parts 21 are formed in the respective substrate support slits 26.
The corners b, 22a, 22c are inserted. First to third
The rigid board portions 21b, 22a, 22c are housed in the inner case 20 in a state where a predetermined distance is maintained by the board supporting slit 26 and the first and second connectors 24, 25.

Further, the upper case member 20a and the lower case member 20b have a tongue-shaped component pressure contact piece 27 protruding inward.
Are provided at several places, and the component pressure contact pieces 27 are in pressure contact with the electronic component 23 and the converter 23a, which generate a large amount of heat, by their leaf spring force. On the other hand, tongue-shaped case pressure contact pieces 28 protruding outward are provided on all four surfaces of the upper case member 20a and the lower case member 20b. The leaf spring force presses the left and right inner surfaces. Therefore, the substrate block C is housed in the case main body A in such a state that it has a minute gap with respect to the inner surface thereof and receives the leaf spring force of the case pressing piece 28.

Further, small holes 19 are formed in the upper case member 20a and the lower case member 20b at positions corresponding to the burr portions of the respective substrate portions 21c, 22a, 22c. That is, each of the substrate parts 21c, 22a, 22c is constructed by a large number of the same kind of substrate parts being connected through a connecting part having a small dimension in the manufacturing stage, and then cut by the connecting part. When this cutting is performed, a burr portion is formed, and if the burr portion is removed, the work efficiency becomes very poor. Therefore, a small hole 19 is formed at a position corresponding to the burr portion of each substrate portion 21c, 22a, 22c so that the inner case 20 can be properly stored even when the burr portion is left.

The rear block body D has a rear panel 29, which is composed of a rear surface portion 29a and a connecting plate portion 29b. A screw hole 30 is formed at an angular position of the rear surface portion 29a in three directions, and a screw 31 inserted into the screw insertion hole 6 of the case body A is screwed into the screw hole 30. The rear block body D is fixed to the rear end side of the case body A by the fastening force of the screw 31. An external connection connector 33 is fixed to the rear surface portion 29a, and a biode signal is output from the external connection connector 33.

As shown in detail in FIGS. 9A and 9B, the connecting means 32 includes a substrate block body C and a rear block body D.
Are integrally connected to each other, and a pair of board end locking claws 34 projecting from the upper and lower ends of the connecting plate portion 29b, and a pair of substrate grooves projecting from the upper and lower ends of the connecting plate portion 29b as well. And an insertion piece portion 35. An inclined projection 35a is provided on the side of the pair of board groove insertion pieces 35 opposite to the board end locking claws.

Notched grooves 36 are formed at both upper and lower ends of the third rigid substrate portion 22c. And
The third rigid board portion 22c is attached to the pair of board end locking claw portions 34.
End portions of the pair of substrate groove insertion pieces 3
5 is inserted in the notch groove 36. For the length L ₁ from the rear end of the third rigid board portion 22c to the end surface of the cutout groove 36, from the board end locking claw portion 34 of the connection plate portion 29b to the end surface of the inclined projection 35a of the board groove insertion piece portion 35. Length of L ₂
Are set to the same or slightly longer. Further, the dimension L ₄ between the pair of substrate groove insertion piece portions 35 is set to be the same or slightly longer than the dimension L ₃ between the end surfaces of the pair of cutout grooves 36.

Further, screw holes 37 are formed at the tip ends of the pair of substrate groove insertion pieces 35, and screw insertion holes 38 are formed in the upper case member 20a and the lower case member 20b of the inner case 20, respectively. Has been formed. Then, the screws 3 inserted into the respective screw insertion holes 38
9 is screwed into the screw hole 37 of the board groove insertion piece 35.

When the front block body B is assembled, the image frame plate 13, the optical filter 14 and the packing member 1 are provided in the optical path space 11 in the cylindrical portion 10 from the rear of the front cylindrical body 7.
5, the CCD package 16 fixed to the back plate 17 is inserted in this order, and then the adjusting ring member 18 is screwed into the tubular portion 10. As a result, assembling of the front block body B is completed as shown in FIG. . Next, while adjusting the distance L between the position of the lens mounting reference plane 8a and the position of the solid-state imaging reference plane with the optical distance measuring device, the adjustment ring member 18 is rotated, for example, clockwise. Then, the pressing portion 18b of the adjusting ring member 18 is displaced to the front side by the pitch of the screw portion 18a, and the packing member 15 is compressed by elastic deformation as shown by a phantom line in FIG. Displace to the side.

When the adjusting ring member 18 is rotated counterclockwise, the pressing portion 18b of the adjusting ring member 18 is displaced to the rear side, the packing member 15 is elastically expanded and the CCD package 16 is displaced to the rear side. To do. After the flange back adjustment is completed by adjusting the distance L to a predetermined value in this way, an adhesive is applied between the tubular portion 10 and the adjustment ring member 18 to make the adjustment ring member 18 unrotatable.

In the above assembly, the CCD package 1
6 is inserted into the optical path space 11 by inserting the four corners into the respective cutout grooves 10a of the tubular portion 10,
As shown in (b), it is possible to accommodate the CCD package 16 whose diagonal dimension d ₁ is slightly larger than the diameter d ₂ of the optical path space 11. The four corners of the CCD package 16 are locked in the respective cutout grooves 10a, so that the CCD package 16 is positioned in the rotational direction.
The CD package 16 is directly positioned on the front cylinder body 7 without positioning parts. Similarly, the optical filter 14 is also housed in the optical path space 11 and positioned on the front cylindrical body 7.

Further, the packing member 15 is inserted into the optical path space 11 by inserting the four locking projections 15f into the respective cutout grooves 10a of the cylindrical portion 10. Then, the elastic force of compression is generated by the pressing force of the adjustment ring member 18, and the opening 15b is deformed in the direction in which the dimension is contracted. Here, since the locking projection 15f located on the diagonal extension of the opening 15b is locked in the notch groove 10b, the locking projection 15f serves as a constraint point for elastic deformation. Therefore, as shown by phantom lines in FIG. 7, elastic deformation due to rotational twist does not occur near the four corners of the opening 15b, and the amount of elastic deformation inward of the opening 15b is small and light vignetting does not occur. .

Further, the crimping projection 15g and each filter holding portion 1
5c is connected via the rib portion 15h, so that as shown by the phantom line in FIG. 7, the portion of the locking projection 15f near the rib portion 15h has an elastic deformation amount toward the inside of the opening 15b. Less vignetting does not occur.

In assembling the board block C, first, the front rigid board portion 21a is fixed to the front block body B and the rear rigid board portion 22e is fixed to the rear block body D by soldering.

Next, as shown in FIG. 8, the first rigid board portion 21c and the second rigid board portion 22a are connected via the first connector 24, and the second rigid board portion 22 is connected.
a and the third rigid board portion 22c are connected via the second connector 25, and the first to third rigid board portions 21c, 22 are connected.
a and 22c are arranged substantially in parallel. Next, this 1st-3rd
The rigid board portions 21c, 22a, 22c are connected to the upper case member 20a and the lower case member 20b of the inner case 20.
The substrate supporting slits 26 of the upper and lower case members 20a, 20b are covered with the respective substrate portions 21c, 22a, 22c.
Insert the horn.

Next, as shown in FIG. 9A, the rear end portion of the third rigid board portion 22c is hooked on the board end hooking claw portion 34 of the rear panel 29. Then, while maintaining this hooked state, a third plate is formed on the surface of the connecting plate portion 29b of the rear panel 29.
Rotate in the direction of arrow A so that the surfaces of the rigid board portion 22c are aligned. Then, each board groove insertion piece portion 35 of the rear panel 29 is inserted into the pair of cutout grooves 36 of the third rigid board portion 22c. When further rotating in the direction of arrow A from this state, the inclined projection 35a of the board groove insertion piece 35 is cut into the cutout groove 36.
Then, as shown in FIG. 9B, both surfaces of the connecting plate portion 29b of the rear panel 29 and the third rigid substrate portion 22c are abutted against each other. In this state, the L ₂ and L ₄ dimensions of the connecting plate portion 29b are the same or slightly larger than the L ₁ and L ₃ dimensions of the third rigid substrate portion 22c described above, so that the third rigid substrate portion 22c receives the compressive force and receives the connecting plate. Part 2
It is temporarily fixed to 9b.

Next, the screws 39 inserted into the screw insertion holes 38 of the upper case member 20a and the lower case member 20b are screwed into the screw holes 37 of the rear panel 29. Then, as shown in FIG.
As shown in, the board block C and the rear block D are integrally fixed via the connecting means 32, and the board block C and the front block B are connected via the flexible board portion 21b. . The block group configured as described above is inserted from the front side of the case main body A from the rear block body D side. Since the substrate block body C and the rear block body D are integrally fixed, the insertion work is easy. Then, when the front block body B is completely inserted, the screw 12 is screwed into the screw hole 9a of the front cylinder body 7 through the screw insertion hole 6 to place the front block body in the case body A and the screw 31 in the screw insertion hole. Screw hole 3 through 6
This is completed by screwing into the 0 and fixing the rear block body D to the case body A, respectively.

When vibrations / impacts are applied to the video camera assembled in this way, the vibrations / impacts are buffered by the case pressure contact pieces 28 and transmitted to the substrate block body C. Further, since the substrate 21 is supported by being inserted into the substrate supporting slit 24 of the inner case 20, the vibrations / impacts transmitted to the substrate block C are not directly transmitted to the substrate 21 but are somewhat buffered and are thus damped on the substrate 21. It is transmitted. From the above, vibrations and shocks from the outside are sufficiently weakened and transmitted to the substrate 21,
Suitable for mounting small electronic components.

In addition, the substrate 21 has the corners thereof at the substrate supporting slits 2 of the upper case member 20a and the lower case member 20b.
Since it is inserted into and supported by the substrate 4, the space required for supporting the substrate 21 is small. Therefore, since the ratio of the component mounting area to the total board area is large, the board 21 itself can be made small and the video camera can be miniaturized.

Further, in connection with the rear block body D, the third
Since only the pair of upper and lower cutout grooves 36 need be formed in the rigid substrate portion 22c, the space required for connection can be reduced.

[0046]

As described above, according to the present invention, four cutout grooves are provided in the tubular portion of the front tubular body, and four corners of the rectangular CCD package are inserted into each of the cutout grooves to form a CC.
Since the D package is housed in the optical path space, a versatile rectangular CCD package can be used without increasing the diameter of the optical path space, resulting in cost reduction and CCD.
Since the package is directly positioned on the front cylinder without using the positioning component, the positioning accuracy is improved.

[Brief description of drawings]

FIG. 1A is an exploded perspective view of a front block body,
FIG. 3B is a cross-sectional view showing the stored state of the CCD package (Example).

FIG. 2 is a perspective view of a video camera (example).

FIG. 3 is an exploded perspective view of a video camera (example).

FIG. 4 is a vertical sectional view of a video camera (example).

FIG. 5 is a cross-sectional view of a video camera (example).

FIG. 6A is a perspective view of the packing member as seen from the front,
(B) is a perspective view of the packing member as seen from the rear (example).

FIG. 7 is a front view of a packing member (embodiment).

FIG. 8 is an exploded perspective view of a substrate block body (Example).

9A and 9B are perspective views (examples) for explaining a step of connecting a substrate block body and a rear block body, respectively.

FIG. 10 is a sectional view of a front block body (embodiment).

FIG. 11 is a perspective view showing an assembled state of the video camera (example).

FIG. 12 is an exploded perspective view of a video camera (example).

FIG. 13 is a vertical sectional view of a video camera (example).

FIG. 14 is a cross-sectional view of a video camera (conventional example).

FIG. 15 is an exploded perspective view of a front block body (conventional example).

FIG. 16 is a sectional view of a front block body (conventional example).

[Explanation of symbols]

 7 ... Front cylinder 10 ... Cylinder part 10a ... Notch groove 11 ... Optical path space 14 ... Optical filter 16 ... CCD package

Claims (2)

[Claims] 1. A front cylindrical portion having an optical path space inside thereof is provided with four notch grooves in the direction of the optical axis which are opened at the rear end of the front end, and each of the notch grooves has a rectangular CCD. A video camera characterized in that a CCD package is arranged in the optical path space by inserting four corners of the package respectively. 2. A front cylindrical body having an optical path space inside thereof is provided with four cutouts in the direction of the optical axis which are opened at the rear end of this front, and each cutout has a rectangular shape. A video camera, wherein the four corners of the optical filter and the CCD package are respectively inserted to arrange the optical filter and the CCD package in the optical path space.